Diversity-Oriented Synthesis

doi:10.1017/CBO9781139021500.007

Chapter 4 - Diversity-Oriented Synthesis

from Section two - Molecules for Chemical Genomics

Published online by Cambridge University Press: 05 June 2012

Warren R. J. D. Galloway ,

Richard J. Spandl ,

Andreas Bender ,

Gemma L. Thomas ,

Monica Diaz-Gavilan ,

Kieron M. G. O’Connell and

David R. Spring

Edited by

Haian Fu

Show author details

Haian Fu: Affiliation:
Emory University, Atlanta

Book contents

Get access

Summary

Introduction

Chemical genetics describes the use of molecules as “chemical probes” to investigate biological systems [1–3]. In contrast with traditional genetics, in which gene knockouts on the level of the DNA are used, chemical genetics uses biologically active small molecules to directly attenuate the corresponding biological macromolecular (usually protein) product. Thus, the ready availability of bioactive small molecules is of crucial importance in chemical genetics studies. Such small molecules can be identified by screening compound collections (libraries) in suitably designed assays. This chapter describes the use of diversity-oriented synthesis (DOS) to prepare structurally diverse small molecule libraries. Structurally diverse libraries show a greater variety in not only their physiochemical properties but also, and of most relevance here, in their biological activities. Herein we describe some of the most effective strategies that have been used in DOS library design and preparation.

Small molecules, chemical genetics, and chemical genomics

Chemical genetics experiments can be performed in either a forward or a reverse sense (Figure 4.1). The first step of both approaches requires the identification of a small molecule that either induces a desired phenotype (forward chemical genetics) or modulates the function of a specific protein of interest (reverse chemical genetics). Thus, in the former case, investigations proceed from phenotype to protein, whereas in the latter case, investigations progress from protein to phenotype.

Type: Chapter
Information: Chemical Genomics , pp. 39 - 59

DOI: https://doi.org/10.1017/CBO9781139021500.007 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2012

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Walsh, D. PChang, Y. T 2006 Chemical geneticsChem Rev 106 2476Google Scholar

Spring, D. R 2005 Chemical genetics to chemical genomics: small molecules offer big insightsChem Soc Rev 34 472Google Scholar

Schreiber, S. L 1998 Chemical genetics resulting from a passion for synthetic organic chemistryBioorg Med Chem 6 1127Google Scholar

Hopkins, A. LGroom, C. R 2002 The druggable genomeNat Rev Drug Discov 1 727Google Scholar

Lipinski, CHopkins, A 2004 Navigating chemical space for biology and medicineNature 432 855Google Scholar

Kaiser, MWetzel, SKumar, KWaldmann, H 2008 Biology-inspired synthesis of compound librariesCell Mol Life Sci 65 1186Google Scholar

Lipinski, C. ALombardo, FDominy, B. WFeeney, P. J 2001 Experimental and computational approaches to estimate solubility and permeability in drug discovery and development settingsAdv Drug Deliv Rev 46 3Google Scholar

Di, LKerns, E. H 2003 Profiling drug-like properties in discovery researchCurr Opin Chem Biol 7 402Google Scholar

Tan, D. S 2005 Diversity-oriented synthesis: exploring the intersections between chemistry and biologyNat Chem Biol 1 74Google Scholar

Haggarty, S. J 2005 The principle of complementarity: chemical versus biological spaceCurr Opin Chem Biol 9 296Google Scholar

Sauer, W. H. BSchwarz, M. K 2003 Molecular shape diversity of combinatorial libraries: a prerequisite for broad bioactivityJ Chem Inf Comput Sci 43 987Google Scholar

Kennedy, J. PWilliams, LBridges, T. MDaniels, R. NWeaver, DLindsley, C. W 2008 Application of combinatorial chemistry science on modern drug discoveryJ Comb Chem 10 345Google Scholar

Estrada, EUriarte, E 2001 Recent advances on the role of topological indices in drug discovery researchCurr Med Chem 8 1573Google Scholar

Fergus, SBender, ASpring, D. R 2005 Assessment of structural diversity in combinatorial synthesisCurr Opin Chem Biol 9 304Google Scholar

Oprea, T. IGottfries, J 2001 Chemography: the art of navigating in chemical spaceJ Comb Chem 3 157Google Scholar

Oprea, T. I 2002 Chemical space navigation in lead discoveryCurr Opin Chem Biol 6 384Google Scholar

Dobson, C. M 2004 Chemical space and biologyNature 432 824Google Scholar

Burke, M. DSchreiber, S. L 2004 A planning strategy for diversity-oriented synthesisAngew Chem Int Ed 43 46Google Scholar

Spandl, R. JSpring, D. R 2008 Diversity-oriented synthesis; a spectrum of approaches and resultsOrg Biomol Chem 6 1149Google Scholar

Adriaenssens, L. VAustin, C. AGibson, MSmith, DHartley, R. C 2006 4998

Spring, D. R 2003 Diversity-oriented synthesis; a challenge for synthetic chemistsOrg Biomol Chem 1 3867Google Scholar

Thomas, G. LWyatt, E. ESpring, D. R 2006 Enriching chemical space with diversity-oriented synthesisCurr Opin Drug Discov Devel 9 700Google Scholar

Nielsen, T. ESchreiber, S. L 2008 Diversity-oriented synthesis – towards the optimal screening collection: a synthesis strategyAngew Chem Int Ed 47 48Google Scholar

Burke, M. DBerger, E. MSchreiber, S. L 2003 Generating diverse skeletons of small molecules combinatoriallyScience 302 613Google Scholar

Shelat, A. AGuy, R. K 2007 Scaffold composition and biological relevance of screening librariesNat Chem Biol 3 442Google Scholar

An, HEum, SKoh, MLee, SPar, S 2008 Diversity-oriented synthesis of privileged benzopyranyl heterocycles from --enonesJ Org Chem 73 1752Google Scholar

Hopkins, A. LMason, J. SOverington, J. P 2006 Can we rationally design promiscuous drugs?Curr Opin Struct Biol 16 127Google Scholar

Clardy, JWalsh, C 2004 Lessons from natural moleculesNature 432 829Google Scholar

Pucheault, M 2008 Natural products: chemical instruments to apprehend biological symphonyOrg Biomol Chem 6 424Google Scholar

Schneider, GGrabowski, K 2007 Properties and architecture of drugs and natural products revisitedCurr Chemical Biol 1 115Google Scholar

Butler, M. S 2004 The role of natural product chemistry in drug discoveryJ Nat Prod 67 2141Google Scholar

Newman, D. JCragg, G. M 2007 Natural products as sources of new drugs over the last 25 yearsJ Nat Prod 70 461Google Scholar

Borman, S 2004 Rescuing CombichemChem Eng News: Sci Technol 82 32Google Scholar

Rouhi, A. M 2003 Rediscovering natural productsChem Eng News 81 88Google Scholar

DeSimone, R. WCurrie, K. SMitchell, S. ADarrow, J. WPippin, D. A 2004 Privileged structures: applications in drug discoveryComb Chem High Throughput Screening 7 473Google Scholar

Koch, M. AWaldmann, H 2005 Protein structure similarity clustering and natural product structure as guiding principles in drug discoveryDrug Discov Today 10 471Google Scholar

Balamurugan, RDekker, F. JWaldmann, H 2005 Design of compound libraries based on natural product scaffolds and protein structure similarity clustering (PSSC)Mol Biosyst 1 36Google Scholar

Breinbauer, RVetter, I. RWaldmann, H 2002 From protein domains to drug candidates – natural products as guiding principles in the design and synthesis of compound librariesAngew Chem Int Ed 41 2879Google Scholar

Goess, B. CHannoush, R. NChan, L. KKirchhausen, TShair, M. D 2006 Synthesis of a 10,000-membered library of molecules resembling carpanone and discovery of vesicular traffic inhibitorsJ Am Chem Soc 128 5391Google Scholar

Ko, S. KJang, H. JKim, EPark, S. B 2006 2962

Cordier, CMorton, DMurrison, SNelson, AO’Leary-Steele, C 2008 Natural products as an inspiration in the diversity-oriented synthesis of bioactive compound librariesNat Prod Rep 25 719Google Scholar

Burke, M. DBerger, E. MSchreiber, S. L 2004 A synthesis strategy yielding skeletally diverse small molecules combinatoriallyJ Am Chem Soc 126 14095Google Scholar

Burke, M. DLalic, G 2002 Teaching target-oriented and diversity-oriented organic synthesis at Harvard UniversityChem. Biol 9 535Google Scholar

Mishra, J. KPanda, G 2007 Diversity-oriented synthetic approach to naturally abundant S-amino acid based benzannulated enantiomerically pure medium ring heterocyclic scaffolds employing inter- and intramolecular Mitsunobu reactionsJ Comb Chem 9 321Google Scholar

Taylor, S. JTaylor, A. MSchreiber, S. L 2004 Synthetic strategy toward skeletal diversity via solid-supported, Otherwise unstable reactive intermediatesAngew Chem Int Ed 43 1681Google Scholar

Wyatt, E. EFergus, SGalloway, W. RBender, AFox, D. JPlowright, A. TJessiman, A. SWelch, MSpring, D. R 2006 3296

Schreiber, S. L 2000 Target-oriented and diversity-oriented organic synthesis in drug discoveryScience 287 1964Google Scholar

Oguri, HSchreiber, S. L 2005 Skeletal diversity via a folding pathway: synthesis of indole alkaloid-like skeletonsOrg Lett 7 47Google Scholar

Thomas, G. LSpandl, R. JGlansdorp, F. GWelch, MBender, ACockfield, JLindsay, J. ABryant, CBrown, D. F. JLoiseleur, ORudyk, HLadlow, MSpring, D. R 2008 Anti-MRSA agent discovery using diversity-oriented synthesisAngew Chem Int Ed 47 2808Google Scholar

Spandl, R. JRudyk, HSpring, D. R 2008 3001

Curran, DLuo, Z. Y 2001 Fluorous techniques for the synthesis and separation of organic moleculesGreen Chem 3 G3Google Scholar

Zhang, W 2003 Fluorous technologies for solution-phase high-throughput organic synthesisTetrahedron 59 4475Google Scholar

Faghih, RDwight, WPan, J. BFox, G. BKrueger, K. MEsbenshade, T. AMcVey, J. MMarsh, KBennani, Y. LHancock, A. A 2003 Synthesis and SAR of aminoalkoxy-biaryl-4-carboxamides: novel and selective histamine H3 receptor antagonistsBioorg Med Chem Lett 13 1325Google Scholar

http://www.symyx.com/products/pdfs/mddr_ds.pdf

Robinson, AThomas, G. LSpandl, R. JWelch, MSpring, D. R 2008 Gemmacin B: bringing diversity back into focusOrg Biomol Chem 6 2978Google Scholar

Kumar, NKiuchi, MTallarico, J. ASchreiber, S. L 2005 Small-molecule diversity using a skeletal transformation strategyOrg Lett 7 2535Google Scholar

Kumagai, NMuncipinto, GSchreiber, S. L 2006 Short synthesis of skeletally and stereochemically diverse small molecules by coupling petasis condensation reactions to cyclization reactionsAngew Chem Int Ed 45 3635Google Scholar

Spiegel, D. ASchroeder, F. CDuvall, J. RSchreiber, S. L 2006 An oligomer-based approach to skeletal diversity in small-molecule synthesisJ Am Chem Soc 128 14766Google Scholar

Koehler, A. NShamji, A. FSchreiber, S. L 2003 Discovery of an inhibitor of a transcription factor using small molecule microarrays and diversity-oriented synthesisJ Am Chem Soc 125 8420Google Scholar

Spring, D. RKrishnan, SBlackwell, H. ESchreiber, S. L 2002 Diversity-oriented synthesis of biaryl-containing medium rings using a one bead/one stock solution platformJ Am Chem Soc 124 1354Google Scholar

Book contents

Chapter 4 - Diversity-Oriented Synthesis

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive